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9: Statics and Torque 10: Rotational Motion and Angular Momentum

9: Statics and Torque 10: Rotational Motion and Angular Momentum. Physics Unit 4. 9.1 The First Condition for Equilibrium 9.2 The Second Condition for Equilibrium. Statics Study of forces in equilibrium Equilibrium means no acceleration First condition of equilibrium and

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9: Statics and Torque 10: Rotational Motion and Angular Momentum

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  1. 9: Statics and Torque10: Rotational Motion and Angular Momentum Physics Unit 4

  2. 9.1 The First Condition for Equilibrium9.2 The Second Condition for Equilibrium • Statics • Study of forces in equilibrium • Equilibrium means no acceleration • First condition of equilibrium • and • They can still rotate, so…

  3. 9.1 The First Condition for Equilibrium9.2 The Second Condition for Equilibrium • Think of opening a door • Which opens the door the best? • Picture a • Big force  large torque • Force away from pivot  large torque • Force directed to door  large torque

  4. 9.1 The First Condition for Equilibrium9.2 The Second Condition for Equilibrium • τ = F × r • This means we use the component of the force that is perpendicular to the lever arm • τ = F r • τ = F r sin θ • θ is the angle between the force and the radius • Unit: Nm • CCW  + • CW  -

  5. 9.1 The First Condition for Equilibrium9.2 The Second Condition for Equilibrium 120° You are meeting the parents of your new “special” friend for the first time. After being at their house for a couple of hours, you walk out to discover the little brother has let all the air out of one of your tires. Not knowing the reason for the flat tire, you decide to change it. You have a 50-cm long lug-wrench attached to a lugnut as shown. If 900 Nm of torque is needed, how much force is needed? F = 2078 N Less force required if pushed at 90°

  6. 9.1 The First Condition for Equilibrium9.2 The Second Condition for Equilibrium • Second condition of equilibrium • Net torque = 0

  7. 9.1 The First Condition for Equilibrium9.2 The Second Condition for Equilibrium • A 5 m, 10 kg seesaw is balanced by a little girl (25 kg) and her father (80 kg) at opposite ends as shown below. How far from the seesaw’s center of mass must the fulcrum be placed? • 1.20 m • How much forcemust the fulcrum support? • 1029 N 80 kg x m 25 kg 10 kg 5 m

  8. Day 37 Homework • Twist out the answers to these torque questions • 9P1-5 • Read 9.3, 9.4 • 9CQ6-8 • Answers • 1) 46.8 Nm • 2) 23.1 Nm, 17.0 ftlb • 3) 23.3 Nm • 4) 568 N • 5) 1.36 m, 686 N

  9. 9.3 Stability9.4 Applications of Statics • Stable equilibrium • When displaced from equilibrium, the system experiences a net force or torque in a direction opposite to the direction of the displacement.

  10. 9.3 Stability9.4 Applications of Statics • Unstable equilibrium • When displaced from equilibrium, the net force or torque is in same direction of the displacement

  11. 9.3 Stability9.4 Applications of Statics • Neutral Equilibrium • Equilibrium is independent of displacement from its original position

  12. 9.3 Stability9.4 Applications of Statics • Problem-Solving Strategy for Static Equilibrium • Is it in equilibrium? (no acceleration or accelerated rotation) • Draw free body diagram • Apply and/or • Choose a pivot point to simplify the problem • Check your solution for reasonableness.

  13. 9.3 Stability9.4 Applications of Statics • The system is in equilibrium. A mass of 225 kg hangs from the end of the uniform strut whose mass is 45.0 kg. Find (a) the tension T in the cable and the (b) horizontal and (c) vertical force components exerted on the strut by the hinge. • Free body diagramnext slide

  14. 9.3 Stability9.4 Applications of Statics

  15. Day 38 Homework • Pick a stable position while you apply your knowledge. • 9P6-7, 9, 11-13, 16-17 • Read 9.5, 9.6 • 9CQ10-12, 15, 17, 19 • Answers • 6) • 7) 1.8 m • 9) 392 N, 196 N • 11) 11.0 N, 0.450 • 12) of the weight, N up • 13) , • 16) along each leg • 17) 126 N, 751 N

  16. 9.5 Simple Machines9.6 Forces and Torques in Muscles and Joints • Machines make work easier • Energy is conserved so same amount of energy with or without machine • Mechanical Advantage (MA)

  17. 9.5 Simple Machines9.6 Forces and Torques in Muscles and Joints • Lever • Uses torques with pivot at N • When F ,

  18. 9.5 Simple Machines9.6 Forces and Torques in Muscles and Joints • Other simple machines • Wheel and Axle • Lever • Inclined Plane • Ramp – less force to slide up, but longer distance • Screw • Inclined plane wrapped around a shaft • Wedge • Two inclined planes

  19. 9.5 Simple Machines9.6 Forces and Torques in Muscles and Joints • Pulley • Grooved wheel • Changed direction of force • In combination, can decrease force

  20. 9.5 Simple Machines9.6 Forces and Torques in Muscles and Joints • What is the mechanical advantage of the inclined plane? • MA = 10 • What is the weight of the cart assuming no friction? • N

  21. 9.5 Simple Machines9.6 Forces and Torques in Muscles and Joints • Muscles only contract, so they come in pairs • Muscles are attached to bones close to the joints using tendons • This makes the muscles supply larger force than is lifted • Input force > output force • MA < 1 • Show video

  22. Day 39 Homework • Machines can’t help you much here, exercise your mental muscles instead • 9P19-24, 29, 31-32, 34-35 • Read 10.1, 10.2 • 10CQ1-4 • Answers • 19) 25.0, 50.0 N • 20) 1.78 m • 21) 18.5, 29.1 N, 510 N • 22) 0.0400 • 23) N • 24) 564 N • 29) N • 31) 470 N • 32) 25 N down, 75 N up • 34) N • 35) N up, 84 N down

  23. 10.1 Angular Acceleration10.2 Kinematics of Rotational Motion • Rotational motion • Describes spinning motion • is like x •  position • is like v •  velocity • is like a •  acceleration

  24. 10.1 Angular Acceleration10.2 Kinematics of Rotational Motion • Two components to acceleration • Centripetal • Toward center • Changes direction only since perpendicular to v • Tangental (linear) • Tangent to circle • Changes speed only since parallel to v

  25. 10.1 Angular Acceleration10.2 Kinematics of Rotational Motion • Equations of kinematics for rotational motion are same as for linear motion

  26. 10.1 Angular Acceleration10.2 Kinematics of Rotational Motion • Reasoning Strategy • Examine the situation to determine if rotational motion involved • Identify the unknowns (a drawing can be useful) • Identify the knowns • Pick the appropriate equation based on the knowns/unknwons • Substitute the values into the equation and solve • Check to see if your answer is reasonable

  27. 10.1 Angular Acceleration10.2 Kinematics of Rotational Motion • A figure skater is spinning at 0.5 rev/s and then pulls her arms in and increases her speed to 10 rev/s in 1.5 s. What was her angular acceleration? • 39.8 rad/s2

  28. 10.1 Angular Acceleration10.2 Kinematics of Rotational Motion • A ceiling fan has 4 evenly spaced blades of negligible width. As you are putting on your shirt, you raise your hand. It brushes a blade and then is hit by the next blade. If the blades were rotating at 4 rev/s and stops in 0.01 s as it hits your hand, what angular displacement did the fan move after it hit your hand?

  29. Day 40 Homework • Spin up your mind and toss out some answers • 10P1-2, 5-8 • Read 10.3, 10.4 • 10CQ5-8, 10 • Answers • 1) 0.737 rev/s • 2) 87.3 rad/s2,8.29 m/s2, m/s2, • 5) 80 rad/s2, 1.0 rev • 6) 405 m • 7) 45.7 s, 116 rev • 8) -25.0 rad/s2,28.7 rev,3.80 s,50.7 m,26.6 m/s,reasonable

  30. 10.3 Dynamics of Rotational Motion10.4 Rotational Kinetic Energy •  Moment of inertia of a particle • Newton’s second law for rotation • α is in rad/s2

  31. 10.3 Dynamics of Rotational Motion10.4 Rotational Kinetic Energy • Moment of Inertia (I) measures how much an object wants to keep rotating (or not start rotating) • Use calculus to find • Unit: • kg m2 • Page 328 lists I for many different mass distributions

  32. 10.3 Dynamics of Rotational Motion10.4 Rotational Kinetic Energy • Work for rotation • Kinetic Energy • Conservation of Mechanical Energy • Remember that the KE can include both translational and rotational.

  33. 10.3 Dynamics of Rotational Motion10.4 Rotational Kinetic Energy • Zorch, an archenemy of Superman, decides to slow Earth’s rotation to once per 28.0 h by exerting an opposing force at and parallel to the equator. Superman is not immediately concerned, because he knows Zorchcan only exert a force of 4.00×107 N (a little greater than a Saturn V rocket’s thrust). How long must Zorch push with this force to accomplish his goal? (This period gives Superman time to devote to other villains.)

  34. 10.3 Dynamics of Rotational Motion10.4 Rotational Kinetic Energy • A solid sphere (m = 2 kg and r = 0.25 m) and a thin spherical shell (m = 2 kg and r = 0.25 m) roll down a ramp that is 0.5 m high. What is the velocity of each sphere as it reaches the bottom of the ramp? • Solid: 2.65 m/s • Shell: 2.42 m/s • Notice masses canceled so mass didn’t matter

  35. Day 41 Homework • Don’t spin your wheels as you use energy to solve these problems • 10P11-15, 22-26, 28, 30 • Read10.5 • 10CQ13-14, 16, 18-20, 25-27 • Answers • 11) • 12) • 13) • 14) , • 15) , , • 22) • 23) , • 24) • 25) • 26) , • 28) • 30) ,

  36. 10.5 Angular Momentum and Its Conservation • Linear momentum • p = mv • Angular momentum • L = Iω • Unit: • kg m2/s • ω must be in rad/s • When you rotate something you exert a torque. • More torque = faster change in angular momentum • Like

  37. 10.5 Angular Momentum and Its Conservation • Linear momentum of a system is conserved if • p0 = pf • Angular momentum of a system is also conserved if • L0 = Lf

  38. 10.5 Angular Momentum and Its Conservation • A 10-kg solid disk with r = 0.40 m is spinning at 8 rad/s. A 9-kg solid disk with r = 0.30 m is dropped onto the first disk. If the first disk was initially not rotating, what is the angular velocity after the disks are together? • ω = 5.31 rad/s • What was the torque applied by the first disk onto the second if the collision takes 0.01 s? • = 215 Nm

  39. 10.6 Collisions of Extended Bodies in 2-D10.7 Gyroscopic Effects: Vector Aspect of L • Angular Momentum conserved if net external torque is zero • Linear Momentum conserved if net external force is zero • Kinetic Energy conserved if elastic collision

  40. 10.6 Collisions of Extended Bodies in 2-D10.7 Gyroscopic Effects: Vector Aspect of L • Direction of angular quantities • Right-hand Rule • Hold hand out with thumb out along axis • Curl your fingers in direction of motion(you may have to turn your hand upside down) • vector in direction of thumb

  41. 10.6 Collisions of Extended Bodies in 2-D10.7 Gyroscopic Effects: Vector Aspect of L • A person is holding a spinning bicycle wheel while he stands on a stationary frictionless turntable. What will happen if he suddenly flips the bicycle wheel over so that it is spinning in the opposite direction?

  42. 10.6 Collisions of Extended Bodies in 2-D10.7 Gyroscopic Effects: Vector Aspect of L • Gyroscopes • Two forces acting on a spinning gyroscope. The torque produced is perpendicular to the angular momentum, thus the direction of the torque is changed, but not its magnitude. The gyroscope precessesaround a vertical axis, since the torque is always horizontal and perpendicular to L . • If the gyroscope is notspinning, it acquires angular momentum in the direction of the torque ( L = ΔL ), and it rotates around a horizontal axis, falling over just as we would expect.

  43. Day 42 Homework • Let you momentum carry you through these problems • 10P36-41 • Read 10.6, 10.7 • 10CQ26-27, 29-30 • Answers • 36) • 37) • 38) • 39) • 40) 25.3 rpm • 41)

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